Scale-free dynamics in physical and biological systems can arise from a variety of causes. Here, we explore a branching process which leads to such dynamics. We find conditions for the appearance of power laws and study quantitatively what happens to these power laws when such conditions are violated. From a branching process model, we predict the behavior of two systems which seem to exhibit near scale-free behavior—rank-frequency distributions of number of subtaxa in biology, and abundance distributions of genotypes in an artificial life system. In the light of these, we discuss distributions of avalanche sizes in the Bak-Tang-Wiesenfeld sandpile model
AbstractFor critical spatially homogeneous branching processes of finite intensity the following dic...
In a semi-infinite geometry, a one-dimensional, M-component model of biological evolution realizes m...
For critical spatially homogeneous branching processes of finite intensity the following dichotomy i...
Scale-free dynamics in physical and biological systems can arise from a variety of causes. Here, we ...
In a critically self-organized model of punctuated equilibrium, boundaries determine peculiar scalin...
The statistics of natural catastrophes contains very counter-intuitive results. Using earthquakes as...
The statistics of natural catastrophes contains very counter-\linebreak intuitive results. Using ear...
Experimental and computational studies provide compelling evidence that neuronal systems are charact...
AbstractA branching process model where offspring distributions depend on the threshold as well as o...
Independence of reproducing individuals can be viewed as the very defining property of branching pro...
Power laws and distributions with heavy tails are common features of many complex systems. Examples ...
We explore, in the mean-field approximation, robustness with respect to dissipation of self-organize...
We give an exact solution of a recently proposed self-organized critical model of biological evoluti...
\ua9 International Institute for Applied Systems Analysis 2005. Biology takes a special place among ...
Branching processes are widely used to model phenomena from networks to neuronal avalanching. In a l...
AbstractFor critical spatially homogeneous branching processes of finite intensity the following dic...
In a semi-infinite geometry, a one-dimensional, M-component model of biological evolution realizes m...
For critical spatially homogeneous branching processes of finite intensity the following dichotomy i...
Scale-free dynamics in physical and biological systems can arise from a variety of causes. Here, we ...
In a critically self-organized model of punctuated equilibrium, boundaries determine peculiar scalin...
The statistics of natural catastrophes contains very counter-intuitive results. Using earthquakes as...
The statistics of natural catastrophes contains very counter-\linebreak intuitive results. Using ear...
Experimental and computational studies provide compelling evidence that neuronal systems are charact...
AbstractA branching process model where offspring distributions depend on the threshold as well as o...
Independence of reproducing individuals can be viewed as the very defining property of branching pro...
Power laws and distributions with heavy tails are common features of many complex systems. Examples ...
We explore, in the mean-field approximation, robustness with respect to dissipation of self-organize...
We give an exact solution of a recently proposed self-organized critical model of biological evoluti...
\ua9 International Institute for Applied Systems Analysis 2005. Biology takes a special place among ...
Branching processes are widely used to model phenomena from networks to neuronal avalanching. In a l...
AbstractFor critical spatially homogeneous branching processes of finite intensity the following dic...
In a semi-infinite geometry, a one-dimensional, M-component model of biological evolution realizes m...
For critical spatially homogeneous branching processes of finite intensity the following dichotomy i...